AEROSPACE DESIGN & ENGINEERING

In the context of rapidly developing modern technology, the Aerospace Design & Engineering major emerges as a field full of potential and opportunities. By integrating aerodynamics, structural mechanics, and automated control systems, this major not only helps improve efficiency and safety in aerospace activities but also opens up many attractive career opportunities. Let's explore the fascinating aspects of this major and find out who is best suited to pursue it.

Program Introduction

The Aerospace Design & Engineering undergraduate program is a crucial part of the aerospace engineering field. It primarily studies the theories and technologies related to the design, manufacturing, testing, and maintenance of aircraft. This program aims to cultivate high-level engineering and technical talents with solid foundational knowledge, professional skills, and innovative abilities, capable of undertaking various technical and management roles within the aerospace industry.

Training Objectives

Aiming at the key technological areas of national aerospace and defense, this program cultivates talents with scientific literacy, engineering literacy, and humanistic spirit. It meets the needs of socialist modernization and new industrial development, systematically mastering the basic theories, methods, and tools of aircraft design, structure, aerodynamics, and control. 

Graduates will have scientific thinking methods and the ability to comprehensively handle scientific and technological problems, capable of engaging in theoretical research, design and development, experimental research, and technical management of aircraft systems in related fields such as aerospace and weapon science and technology.

Approximately five years after graduation, students are expected to achieve the following goals:

1. Possess noble morals and humanistic literacy;
2. Effectively apply engineering technical standards to design technical solutions for aircraft systems;
3. Have good team organization, coordination, communication, and competitive and cooperative abilities;
4. Serve as technical backbones or key roles in the field of aircraft design and related professional fields;
5. Have the awareness of lifelong learning and the ability to learn independently and adapt to development;
6. Have the ability to engage in international exchanges and cooperation and serve local, national, and global societies.

Graduation Requirements

Graduate Competency Requirements

Students in this program mainly study related natural science knowledge such as mathematics, physics, and computer languages, basic theories and knowledge of mechanics, machinery, electrical circuits, and testing, as well as basic theories and professional knowledge of aircraft overall design, aircraft structure design, aerodynamics, and principles of aircraft guidance and control. 

They receive basic training in system design, technical analysis, product development, experimental testing, and engineering management, and have the ability to use engineering knowledge and modern tools to carry out overall design, aerodynamic design, structural analysis and design, and spacecraft design of aircraft systems, and to handle and analyze practical problems.

Graduates should acquire the following knowledge and abilities:

1. Engineering Knowledge: Apply mathematics, natural sciences, engineering fundamentals, and professional knowledge to solve complex aerospace engineering problems.
2. Problem Analysis: Apply basic principles of mathematics, natural sciences, and engineering sciences to identify, express, and analyze complex aerospace engineering problems through literature research to obtain effective conclusions.
3. Design/Develop Solutions: Design solutions for complex aerospace engineering problems, design aircraft systems, units (components), or processes that meet specific needs, and demonstrate innovative consciousness in the design process, considering social, health, safety, legal, cultural, and environmental factors.
4. Research: Conduct research on complex aerospace engineering problems based on scientific principles and methods, including designing experiments, analyzing and interpreting data, and obtaining reasonable and effective conclusions through information synthesis.
5. Use Modern Tools: Develop, select, and use appropriate technologies, resources, modern engineering tools, and information technology tools for complex aerospace engineering problems, including prediction and simulation of complex aerospace engineering problems, and understand their limitations.
6. Engineering and Society: Conduct reasonable analysis based on aerospace engineering-related background knowledge, evaluate the impact of professional engineering practices and solutions to complex engineering problems on society, health, safety, legal, and cultural aspects, and understand the responsibilities to be undertaken.
7. Environment and Sustainable Development: Understand and evaluate the impact of engineering practices on the environment and social sustainable development for complex aerospace engineering problems.
8. Professional Norms: Possess humanistic and social science literacy, social responsibility, understand and adhere to engineering professional ethics and norms in aerospace engineering practice, and fulfill responsibilities.
9. Individual and Team: Play the role of individual, team member, and leader in a team with a multidisciplinary background.
10. Communication: Effectively communicate and exchange with industry peers and the public on complex aerospace engineering problems, including writing reports and design documents, making presentations, clearly expressing or responding to instructions, and having an international perspective to communicate and exchange in a cross-cultural context.
11. Project Management: Understand and master engineering management principles and economic decision-making methods, and apply them in a multidisciplinary environment.
12. Lifelong Learning: Have the awareness of autonomous learning and lifelong learning, and the ability to continuously learn and adapt to development.

Graduation Credit Requirements

Complete the required number of credits as stipulated in the university's academic program.

Core Courses

• Introduction to Aerospace Technology
• Aerodynamics
• Flight Mechanics
• Principles of Aircraft Guidance and Control
• Aircraft Structural Mechanics
• Aircraft Attitude Control System Design
• Overall Aircraft Design
• Comprehensive Aircraft System Experiment
• Aircraft Manufacturing Technology
• Aircraft Structural Dynamics

Research Directions

• Overall Aircraft Design
• Aircraft Structure and Materials
• Aircraft Power Systems
• Aircraft Control and Navigation
• Aircraft Manufacturing and Testing

Degree Awarded

Students who complete all courses in the Aerospace Design & Engineering program and meet the graduation requirements will be awarded a Bachelor of Aerospace Design & Engineering degree.

Career Development

Graduates can work in research institutes, design units, manufacturing enterprises, and higher education institutions in the aerospace field, engaging in aircraft design, manufacturing, testing, maintenance, and management. Specific positions include aircraft design engineer, structural engineer, systems engineer, test engineer, etc. Additionally, graduates can pursue master's and doctoral degrees for more in-depth research work.

Related Majors

• Aerospace Engineering
• Aeronautical Engineering
• Avionics Technology
• Aircraft Mechanical and Electrical Equipment Maintenance

Top Universities Offering Aerospace Design & Engineering Programs in China

1. Beihang University (Beijing University of Aeronautics and Astronautics)
2. Tsinghua University
3. Northwestern Polytechnical University
4. Nanjing University of Aeronautics and Astronautics
5. Harbin Institute of Technology
6. Shanghai Jiao Tong University
7. Zhejiang University
8. Southeast University